Provided by: libtie-array-iterable-perl_0.03-2_all bug

NAME

       Tie::Array::Iterable - Allows creation of iterators for lists and arrays

SYNOPSIS

         use Tie::Array::Iterable qw( quick );

         my $iterarray = new Tie::Array::Iterable( 1..10 );
         for( my $iter = $iterarray->start() ; !$iter->at_end() ; $iter->next() ) {
               print $iter->index(), " : ", $iter->value();
               if ( $iter->value() == 3 ) {
                       unshift @$iterarray, (11..15);
               }
         }

         my @array = ( 1..10 );
         for( my $iter = iterator_from_start( @array ) ;
                  !$iter->at_end() ;
                  $iter->next() ) { ... }

         for( my $iter = iterate_from_end( @array ) ;
              !$iter->at_end() ;
                  $iter->next() ) { ... }

DESCRIPTION

       "Tie::Hash::Iterable" allows one to create iterators for lists and arrays.  The concept of
       iterators is borrowed from the C++ STL [1], in which most of the collections have
       iterators, though this class does not attempt to fully mimic it.

       Typically, in C/C++ or Perl, the 'easy' way to visit each item on a list is to use a
       counter, and then a for( ;; ) loop.  However, this requires knowledge on how long the
       array is to know when to end.  In addition, if items are removed or inserted into the
       array during the loop, then the counter will be incorrect on the next run through the
       loop, and will cause problems.

       While some aspects of this are fixed in Perl by the use of for or foreach, these commands
       still suffer when items are removed or added to the array while in these loops.  Also, if
       one wished to use break to step out of a foreach loop, then restart where they left at
       some later point, there is no way to do this without maintaining some additional state
       information.

       The concept of iterators is that each iterator is a bookmark to a spot, typically
       considered between two elements.  While there is some overhead to the use of iterators, it
       allows elements to be added or removed from the list, with the iterator adjusting
       appropriate, and allows the state of a list traversal to be saved when needed.

       For example, the following Perl code will drop into an endless block (this mimics the
       functionality of the above code):

          my @array = (0..10);
          for my $i ( @a ) {
              print "$i\n";
                  if ( $i == 3 ) { unshift @a, ( 11..15 ); }
          }

       However, the synopsis code will not be impaired when the unshift operation is performed;
       the iteration will simply continue at the next element, being 4 in this case.

       Tie::Array::Iterable does this by first tying the desired list to this class as well as
       blessing it in order to give it functionality.  When a new iterator is requested via the
       iterable array object, a new object is generated from either
       Tie::Array::Iterable::ForwardIterator or Tie::Array::Iterable::BackwardIterator.  These
       objects are then used in associated for loops to move through the array and to access
       values.  When changes in the positions of elements of the initial array are made, the tied
       variable does the appropriate bookkeeping with any iterators that have been created to
       make sure they point to the appropriate elements.

       Note that the iterable array object is also a tied array, and thus, you can use all
       standard array operations on it (with arrow notation due to the reference, of course).

       The logic behind how iterators will 'move' depending on actions are listed here.  Given
       the list

           0 1 2 3 4 5 6 7 8 9 10
                    ^
                    Forward iterator current position

       Several possible cases can be considered:

       unshift
           If an item was unshifted on the list, thus pushing all elements to the right, the
           iterator will follow this and will still point to 5.

       shift
           Removing an item from the start of the list will push all elements to the left, and
           the iterator again will follow and point to 5.

       pop, push
           Since these affect the list after the position of the iterator, there is no change in
           the iterator at this time.  However, an iterator that is at the end of the list will
           pass over these new elements if it is moved backwards though the list.

       splice 3, 4, ()
           If the array is spliced from 3 to 6, then the position that the iterator is at is
           invalid, and is pushed back to the last 'valid' entry, this being between 2 and 7
           after the splice and pointing to 7.

       splice 3, 4, ( 11, 12, 13 )
           Even though we are adding new data, this is similar to the situation above, and the
           iterator will end up pointing at 11, sitting between 2 and 11.

       splice 4, 0, ( 11, 12, 13 )
           This will push extra data between 3 and 4, but does not affect the position of the
           iteration, which will still point at 5.

       splice 5, 0, ( 11, 12, 13 )
           Because the data is now being pushed between 4 and 5, this will affect the iterator,
           and the iterator will now point at 11.

       splice 0, 6
           Remove all data from the head to the iterator position will result it in being at the
           leftmost part of the array, and will be pointing at 7.

       This is only for the forward iterator; the backwards iterator would work similarly.

   PACKAGE METHODS
       new( [<array>] )
           Creates a new iterable array object; this is returned as a reference to an array.  If
           an array is passed, then the iterable array is set up to use this array as storage.

       iterate_from_start( <list> )
           Returns a forward iterator that can be used to iterator over the given list.  This
           allows one to avoid explicitly creating the iterable array object first, though one
           still is created for this purpose.

       iterate_from_end( <list> )
           Returns a backwards iterator that can be used to iterate over the given list.

       iterate_forward_from( <int>, <list> )
           Returns a forward iterator for the given list set at the indicated position.

       iterate_backward_from( <int>, <list> )
           Returns a backward iterator for the given list set at the indicated position.

   CLASS METHODS
       from_start( )
           Returns a new forward iterator set at the start of the array.  Parentheses are not
           required.

       from_end( )
           Returns a new backward iterator set at the end of the array.  Parentheses are not
           required.

       forward_from ([<int>])
           Returns a new forward iterator set at the indicated position (or at the start of the
           array if no value is passed).

       backward_from ([<int>])
           Returns a new backward iterator set at the indicated position (or at the end of the
           array if no value is passed).

       clear_iterators( )
           This function was previously used to clear references that might accumulate; however,
           this functionality has been fixed, and this function does nothing besides return a
           true value.

   ITERATOR METHODS
       The iterators that are generated by the functions above have the following functions
       associated with them.

       value()
           Returns the current value from the array where the iterator is pointing, or undef if
           the iterator is at the end.

       set_value( <value> )
           Sets the value of the array where the iterator is currently positions to the passed
           value.  This will do nothing if the iterator is at the end of the array.

       index()
           Returns the index in the array where the iterator is currently pointing.

       set_index( <pos> )
           Moves the iterator to this position in the array.

       at_end()
           Returns true if the iterator is pointing at the end position (at the end of the array
           for a Forward iterator, at the start of the array for the Backward iterator), false
           otherwise.  Parentheses are not required.

       at_start()
           Returns true if the iterator is pointing at the start position (at the beginning of
           the array for a Forward iterator, at the end of the array for the Backward iterator),
           false otherwise.  Parentheses are not required.

       next()
           Advances the iterator to the next position; the value of this new position is returned
           as per "value()".  This will not move past the end position.  Parentheses are not
           required.

       prev()
           Advances the iterator to the previous position; the value of this new position is
           returned as per "value()".  This will not move past the starting position.
           Parentheses are not required.

       to_end()
           Advances the iterator to the very end position.  Note that this is the undefined
           state, and the only way to resume traversal is to move to preceding elements.  Also
           note that for a backwards iterator, this means to move to the beginning of the array.
           Parentheses are not required.

       to_start()
           Advances the iterator back to the starting position for the iterator.  Again, for a
           backwards iterator, this means moving to the end of the list.  Parentheses are not
           required.

       forward( [<int>] )
           Advances the iterator in the forward direction the number of steps passed, or just 1
           if no value is passed (and thus acting like "next()").

       backward( [<int>] )
           Advances the iterator in the backward direction the number of steps passed, or just 1
           if no value is passed (and thus acting like "prev()").

EXPORT

       The 'quick' export will export "iterate_from_start", "iterate_from_end",
       "iterate_forward_from", and "iterate_backward_from" functions into the global namespace.
       Optionally, you may import these functions individually.

CAVAETS

       You should not directly tie your array to this class, nor use the ForwardIterator or
       BackwardIterator classes directly.  There are factory-like methods for these classes that
       you should use instead.

       You might run in to trouble if you use more than MAXINT (typically 2^32 on most 32-bit
       machines) iterators during a single instance of the program.  If this is a practical
       concern, please let me know; that can be fixed though with some time consumption.

AUTHOR

       Michael K. Neylon <mneylon-pm@masemware.com>

ACKNOWLEDGEMENTS

       I'd like to thank Chip Salzenberg for a useful suggesting in helping to remove the
       reference problem without having to resort to weak references on Perlmonks.

REFERENCES

       [1] A reference guide to the C++ STL can be found at
           http://www.cs.rpi.edu/projects/STL/htdocs/stl.html

COPYRIGHT

       Copyright 2001 by Michael K. Neylon <mneylon-pm@masemware.com>.

       This program is free software; you can redistribute it and/or modify it under the same
       terms as Perl itself.

       See http://www.perl.com/perl/misc/Artistic.html